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L 23 – Vibrations and Waves [3] • resonance clocks – pendulum • springs harmonic motion mechanical waves sound waves golden rule for waves Wave interference standing waves – beats musical instruments

L 23 – Vibrations and Waves [3] resonance clocks – pendulum springs harmonic motion mechanical waves sound waves golden rule for waves Wave

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L 23 – Vibrations and Waves [3]

• resonance • clocks – pendulum • springs • harmonic motion • mechanical waves • sound waves • golden rule for waves• Wave interference

– standing waves– beats

• musical instruments

Review

• A mechanical wave is a disturbance that travels through a medium – solids, liquids or gases – it is a vibration that propagates

• The disturbance moves because of the elastic nature of the material

• As the disturbance moves, the parts of the material (segment of string, air molecules) execute harmonic motion (move up and down or back and forth)– transverse wave– longitudinal wave

transverse & longitudinal waves

the string motion in vertical but the wave moves in the horizontal (perpendicular) direction transverse wave

the coils of the slinky movealong the same direction(horizontal) as the wave longitudinal wave

Harmonic waves

• each segment of the string undergoes simple

harmonic motion as the wave passes by• Look at a snapshot of the string at some time• distance between successive peaks is called the

WAVELENGTH (lambda), it is measured in meters or cm

The golden rule for waves• The “golden rule” is the relationship between

the speed (v) of the wave, the wavelength (l) and the period (T) or frequency ( f )

• recall that T = 1 / f, f = 1/T • it follows from speed = distance / time• the wave travels one wavelength in one period,

so wave speed v = / T, but since f = 1 / T, we have

• v = f• this is the “Golden Rule” for waves

Example: wave on a string

• A wave moves on a string at a speed of 4 cm/s• A snapshot of the motion shows that the

wavelength, is 2 cm, what is the frequency, ?• v = , so = v ÷ = (4 cm/s ) / (2 cm) = 2 Hz• T = 1 / f = 1 / (2 Hz) = 0.5 s

2 cm 2 cm 2 cm

SOUND WAVES

• longitudinal pressure disturbances in a gas

• the air molecules jiggle back and forth in the same direction as the wave

• Sound speed in air is 343 m/s

S N

Patm

Tuning forks make sound waves

• The vibration of the fork causes the air near it to vibrate

• The length of the fork determines the frequency– longer fork lower f– shorter fork higher f

• It produces a pure pitch single frequency

Stringed instruments

• Three types– Plucked: guitar, bass, harp, harpsichord– Bowed: violin, viola, cello, bass– Struck: piano

• All use strings that are fixed at both ends– Use different diameter strings (mass per unit

length is different)– The string tension is adjustable - tuning

Standing waves

• standing waves are produced by wave interference

• when a transverse wave is launched on a string a reflected wave is produced at the other end

• the incident and reflected waves interfere with each other to produce a standing wave

Constructive interference Destructive interference

Waves add todouble amplitude

Launch 2 up-going pulses on string Launch 1 up-going and 1 down-goingpulses on string

waves add to give zero amplitude

Standing waves

• At the NODE positions, the string does not move

• At the ANTINODES the string moves up and down harmonically

• Only certain wavelengths can fit into the distance L

• The frequency is determined by the velocity and mode number (wavelength)

Vibration modes of a string

L

L

Fundamental modeWavelength = 2 LFrequency = fo

First harmonic modeWavelength = LFrequency = 2 fo

N N

N N N

A

AA

N = nodes, A = antinodes

Vibration frequencies

• In general, f = v / , where v is the propagation speed of the string

• The propagation speed depends on the diameter and tension

• Modes– Fundamental: fo = v / 2L

– First harmonic: f1 = v / L = 2 fo

• The effective length can be changed by the musician “fingering” the strings

Bowed instruments

• In violins, violas, cellos and basses, a bow made of horse hair is used to excite the strings into vibration

• Each of these instruments are successively bigger (longer and heavier strings).

• The shorter strings make the high frequencies and the long strings make the low frequencies

• Bowing excites many vibration modes simultaneously mixture of tones (richness)

Organ pipes

• The air pressure inside the pipe can vibrate, in some places it is high and in other places low

• Depending on the length of the pipe, various resonant modes are excited, just like blowing across a pop bottle

• The long pipes make the low notes, the short pipes make the high notes

Gravissima 8.2 Hz

4400 Hz

St. Vincent’s Episcopal Church in Bedford, Texas

Beats – wave interference

• Waves show a special property called interference

• When two waves are combined together, the waves can add or subtract

• We call this constructive and destructive interference

• When a wave is launched on a string it can reflect back from the far end. The reflected wave can combine with the original wave to make a standing wave

Combining 2 waves of the same frequency

Red + Blue

Combining 2 waves of slightly different frequencies

BeatsRed + Blue

Room Acoustics

• Destructive interference accounts for bad room acoustics

• Sound that bounces off a wall can interfere destructively (cancel out) sound from the speakers resulting in dead spots

Wave interference can be used to eliminate noise – anti-noise technology

Take one wave, turn itupside down (invert itsphase) then add it tothe original wave

Noise elimination headphones